Atom Collection (page 9)

Pentachlorophenol molecule
Pentachlorophenol (PCP), molecular model. Organochlorine compound used as a pesticide and a disinfectant. Atoms are represented as spheres and are colour-coded: carbon (grey)

Alanine molecule
Alanine, molecular model. Alpha-amino acid that can be synthesised by the body. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (blue-green)

Proline molecule
Proline, molecular model. Non-essential alpha-amino acid, one of the 20 DNA-encoded amino acids. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (blue-green)

Leucine molecule
Leucine, molecular model. Essential alpha-amino acid contained in eggs, soy protein, seaweed, turkey, chicken, lamb, cheese, and fish

Cysteine Molecule
Cysteine, molecular model. Non-essential alpha-amino acid. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (blue-green), nitrogen (blue)

Thujone molecule
Thujone, molecular model. Organic compound with menthol odour found in the spirit absinthe. Thujone acts as a GABA-A receptor antagonist

Glutamine molecule
Proline, molecular model. Non-essential alpha-amino acid, one of the 20 DNA-encoded amino acids. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (blue-green)

Chemical research, conceptual image

Isoleucine molecule
Isoleucine, molecular model. Essential alpha-amino acid contained in eggs, soy protein, seaweed, turkey, chicken, lamb, cheese, and fish

Threonine molecule
Threonine, molecular model. Essential alpha-amino acid and one of the 20 proteinogenic amino acids. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (blue-green)

Valine molecule
Valine, molecular model. Essential alpha-amino acid and one of the 20 proteinogenic amino acids. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (blue-green)

Phenylalanine molecule
Phenylalanine, molecular model. Essential alpha-amino acid, one of the 20 common amino acids used to form proteins. Atoms are represented as spheres and are colour-coded: carbon (grey)

Tryptophan molecule
Tryptophan, molecular model. Essential amino acid and one of the 20 standard amino acids. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (blue-green)

Methionine molecule
Methionine, molecular model. Essential alpha-amino acid. Atoms are represented as spheres and are colour-coded: carbon (grey), hydrogen (blue-green), nitrogen (blue), oxygen (red) and sulfur (yellow)

Graphene sheets, artwork F008 / 3366
Graphene sheets, computer artwork

Praseodymium, atomic structure
Bismuth (Bi). Diagram of the nuclear composition, electron configuration, chemical data, and valence orbitals of an atom of bismuth-209 (atomic number: 83), the most common isotope of this element

Organic chemistry building blocks C017 / 3599
Organic chemistry building blocks, conceptual image. Computer artwork showing how carbon (C, black) oxygen (O, red) and hydrogen (H)

Structure of matter, artwork C018 / 0948
Structure of matter. Computer artwork representing the Standard Model of particle physics. Shown here is a molecule of water (top centre)

Adenine molecule, artwork C017 / 7199
Adenine molecule. Computer artwork showing the structure of a molecule of the nucleobase adenine. Atoms are colour-coded spheres: carbon (green), nitrogen (blue), and oxygen (white)

Phosphorus, atomic structure C018 / 3696
Argon (Ar). Diagram of the nuclear composition, electron configuration, chemical data, and valence orbitals of an atom of argon-40 (atomic number: 18)

Lomitapide hypercholesterolemia drug F007 / 0160
Lomitapide hypercholesterolemia drug, molecular model. Lomitapide is used in the treatment of homozygous familial hypercholesterolemia

Vortioxetine antidepressant drug F007 / 0207
Vortioxetine antidepressant drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), sulfur (yellow) and nitrogen (blue)

Vortioxetine antidepressant drug F007 / 0206
Vortioxetine antidepressant drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), sulfur (yellow) and nitrogen (blue)

Vortioxetine antidepressant drug F007 / 0205
Vortioxetine antidepressant drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), sulfur (yellow) and nitrogen (blue)

Vemurafenib melanoma drug F007 / 0204
Vemurafenib melanoma drug, molecular model. Vemurafenib is a B-Raf enzyme inhibitor used in the treatment of melanoma skin cancer

Vemurafenib melanoma drug F007 / 0203
Vemurafenib melanoma drug, molecular model. Vemurafenib is a B-Raf enzyme inhibitor used in the treatment of melanoma skin cancer

Triphenylene hydrocarbon molecule F007 / 0202
Triphenylene polycyclic aromatic hydrocarbon (PAH), molecular model. Triphenylene is an environmental pollutant and suspected to be carcinogenic, mutagenic and teratogenic

Triphenylene hydrocarbon molecule F007 / 0201
Triphenylene polycyclic aromatic hydrocarbon (PAH), molecular model. Triphenylene is an environmental pollutant and suspected to be carcinogenic, mutagenic and teratogenic

Treprostinil drug, molecular model F007 / 0200
Treprostinil drug, molecular model. Treprostinil is used in the treatment of pulmonary arterial hypertension. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey)

Treprostinil drug, molecular model F007 / 0199
Treprostinil drug, molecular model. Treprostinil is used in the treatment of pulmonary arterial hypertension. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey)

Trametinib melanoma cancer drug F007 / 0198
Trametinib melanoma cancer drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), fluorine (dark yellow)

Trametinib melanoma cancer drug F007 / 0197
Trametinib melanoma cancer drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), fluorine (dark yellow)

Tofacitinib rheumatoid arthritis drug F007 / 0196
Tofacitinib rheumatoid arthritis drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red) and nitrogen (blue)

Tofacitinib rheumatoid arthritis drug F007 / 0195
Tofacitinib rheumatoid arthritis drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red) and nitrogen (blue)

Teriflunomide multiple sclerosis drug F007 / 0194
Teriflunomide multiple sclerosis drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), fluorine (dark yellow) and nitrogen (blue)

Sumatriptan migraine headache drug F007 / 0192
Sumatriptan migraine headache drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), sulfur (yellow) and nitrogen (blue)

Sumatriptan migraine headache drug F007 / 0190
Sumatriptan migraine headache drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), sulfur (yellow) and nitrogen (blue)

Sumatriptan migraine headache drug F007 / 0191
Sumatriptan migraine headache drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), sulfur (yellow) and nitrogen (blue)

Riociguat pulmonary hypertension drug F007 / 0189
Riociguat pulmonary hypertension drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), fluorine (dark yellow) and nitrogen (blue)

Riociguat pulmonary hypertension drug F007 / 0188
Riociguat pulmonary hypertension drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), fluorine (dark yellow) and nitrogen (blue)

Regorafenib colorectal cancer drug F007 / 0187
Regorafenib colorectal cancer drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), chlorine (green)

Regorafenib colorectal cancer drug F007 / 0186
Regorafenib colorectal cancer drug, molecular model. Atoms are represented as spheres and are colour-coded: hydrogen (white), carbon (grey), oxygen (red), chlorine (green)

Prostaglandin I2 drug molecule F007 / 0185
Prostaglandin I2 (PGI2, epoprostenol) pulmonary hypertension drug, molecular model. PGI2 is an eicosanoid drug that inhibits platelet activation and causes vasodilation

Prostaglandin I2 drug molecule F007 / 0184
Prostaglandin I2 (PGI2, epoprostenol) pulmonary hypertension drug, molecular model. PGI2 is an eicosanoid drug that inhibits platelet activation and causes vasodilation

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"Unveiling the Mysteries of the Atom: From Northern Lights to Quantum Leaps" In the ethereal dance of the Northern lights, nature showcases its own version of atomic beauty. Much like these mesmerizing lights, our understanding of atoms has evolved through groundbreaking scientific discoveries. One such milestone occurred in E. Rutherford's Cavendish Laboratory, where he unraveled the atom's structure and introduced us to its nucleus. This pivotal moment paved the way for Niels Bohr's caricatured quantum model, depicting electrons orbiting around a central core. The power within an atom is not limited to theory alone; it manifests itself in nuclear fission artwork that captures both its destructive force and potential energy release. Similarly, Britain's Ariel Atom embodies this dynamism with its sleek design and exhilarating speed. Delving deeper into atomic intricacies reveals Immunoglobulin G antibody molecule F007/9894 - a crucial defender against pathogens within our immune system. Its intricate structure mirrors the complexity hidden within every atom. Just as science progresses, so does technology - exemplified by Ariel Atom 500 and its cutting-edge engineering prowess. It pushes boundaries much like artists who depict atomic structures in captivating artworks or scientists who unveil quantized orbits resembling those found in celestial bodies' paths. Peering into helium atoms' electron structures unveils their unique properties while HIV reverse transcription enzyme sheds light on how viruses manipulate genetic material at an atomic level. Finally, we arrive at 2009 Ariel Atom - embodying innovation and evolution just as our understanding of atoms continues to expand exponentially. From enchanting natural phenomena like Northern lights to pioneering research conducted by brilliant minds like Rutherford and Bohr; from artistic interpretations capturing atomic wonders to technological marvels pushing limits – each hint represents a facet of humanity's ceaseless quest to unravel the enigmatic world of atoms.